JPH0759409B2 - Automatic gun for fastening pieces - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention provides a flexible plastic clamp having a flat tail and an open head at the front end around a bundle such as a cable. For automatic guns for wrapping around.

(Prior Art) British Patent No. 2,072,614 discloses an automatic gun in which fastening pieces are arranged side by side and which are connected by a connecting member, that is, a fastening piece in the form of a belt.
It is disclosed for the first time.

This configuration has enormous advantages for delivery to the gun. This is because the fastening pieces can be shaped in the form of strips and, unlike in other guns, the fastening pieces need not be individually integrated inside the magazine.

The gun described in British Patent No. 2,072,614 is
An indexing device for advancing the band so that the leading fastening piece of the band moves stepwise in the lateral direction to reach the ready position in the gun, a device for cutting the leading fastening piece from the band, a tail A device for ejecting the fastening piece in the ready position headed from the gun with the tail at the top, and the fastening piece is fed from the gun, the free end of the tail passing through the head with the opening and engaging with the head. When arranged to do so, it includes a device at the front end of the gun that guides the tail of the clamp about the bundle to be gathered.

Further, the gun engages the free end of the tail (once it has passed through the apertured head) and drives the free end to pull the fastening pieces around the bundle to be assembled, At the rear of the head, when the knife that cuts the tail and the tensile stress of the fastening piece reach a predetermined value,
It includes a tensile stress detector for actuating the knife.

In the gun shown in the drawing of British Patent No. 2,072,614, a reciprocating push rod is attached in order to push the clamping piece out of the gun, with the tail leading. The push rod engages the free end of the tail (once it has passed through the head with the opening), and the return movement of the push rod pulls the tail through the head, pulling stress on the fastening piece. Is equipped with a device adapted to give.

However, the length required for the stroke of the push rod necessarily results in an undesirably large length of the gun. For this reason, there is a demand that something that can be held by hand when used, and that is small and lightweight, is preferable.

(Means for Solving the Problems) According to the present invention, there is provided an automatic gun in which a flexible integral plastic fastening piece is wound around a bundle such as a cable,
Each fastening piece has a flat tail, the tail having a tip at one end, a head having an opening at the other end, and a plurality of serrations on one side, wherein the automatic gun comprises: A means for advancing each tightening piece to a predetermined position where one end is close to the front part of the gun and the head is far from the front part of the gun, and the tightening piece at this predetermined position has a tail leading from the front part of the gun And the fastening piece is driven from the gun so that the tip of the tail passes through the head and is connected in it so that the fastening piece tail is wrapped around the bundle to be wrapped. A guide means provided at the front end of the gun for guiding, the means for driving the fastening piece from the gun with the tail at the front is a pinch wheel,
It comprises a drive means for rotating the pinch wheel and a cam wheel, which is normally stationary, the pinch wheel and the cam wheel being arranged behind the guide means, between which the flat of the fastening piece is located. Spaced so as to sandwich the tail, the pinch wheel engages serrations on one side of the tail and contacts the outer surface of the cam wheel on the opposite side of the tail so that the fastening piece pivots on the pinch wheel. Is driven forward, the cam wheel is provided with a concave portion, and the head of the fastening piece of the concave portion is accommodated therein. Further, detection of entry of the head into the concave portion is performed. And a means for rotating the cam wheel by 360 degrees by the driving means, and when the cam wheel rotates, the recess has a surface that supports the rear end of the head, An automatic gun piece tightening is adapted to push up the final position of the forward motion is provided a.

(Examples) Examples of the present invention will be described below with reference to the accompanying drawings. The examples do not limit the invention.

Fastening strip band In FIGS. 1 and 2, the fastening strip band (1) has a fastening strip (10), and the fastening strip (10) is a narrow strip (12) (14). Are connected in a line by.

The strips (12) (14) linearly pass between the tail tip (18) and the fastening piece head (16), respectively.
A tail tip (18) and a head (16) respectively,
They are connected by short filaments (12a) (14a).

In each clamp, the tail has one side molded with a series of lateral ratchet serrations (22) and a head (16) projects at one end of the tail. The head (16) is wider than the tail.

The head (16) has an opening (26) extending from the side having the serration of the tail so as to be substantially orthogonal to the tail surface.

A series of serrations (22) extend to the inlet side of the opening (26) as shown. Inside the opening (26), a swingable pawl (28) having teeth complementary to the ratchet serration of the tail is formed.

As the free end of the tail passes through the head from the entrance side of the opening, the pawl allows the free passage of the tail,
Get on the serrations. However, the return movement of the tail
Prevented by the engagement of the claws in the head with the serrations on the tail.

Generalized automatic gun for fastening pieces Fig. 1 and Fig. 2 show fastening pieces in an automatic gun.
The gun is portable, which meets the requirements of being lightweight, compact and easy to use.

One motor is the only power plant, and current is supplied to the gun from a separately mounted power pack by conventional leads. Therefore, the operability of this handheld gun has very few restrictions. Also, in order to minimize this limitation, it is preferred that the bands of each fastening strip be relatively short, eg, each band will typically have from 20 to 100 fastening strips. Even so, there is no problem because the work of engaging the new band with the gun is quick and easy.

3 to 8 show the gun structure and the basic principle of operation.

This gun has a long indexing drum (30) (Figs. 3 and 4).
Figure) and the axis of this drum is from the front to the rear of the gun. The drum (30) has several discs mounted at intervals along a rotatable axis. On the periphery of each disc are five recesses (3
2) is provided. The recesses of the disks are at the same positions as the recesses of the other disks.

Thus, the drum receives successive clamps in the band at five equally spaced locations along its periphery.

As shown in FIG. 3, the gate (34) is located on one side of the gun (right side when viewed from the front) and can be rotated around the shaft (36) at a position lower than the drum (30). You can This rotation is performed manually.

In FIG. 3, the gate is remote from the drum and is in the receiving position. In this receiving position, the band (1) can be inserted into the gate through the slot (38). The gate, when the strip is inserted through the inlet slot (38),
It has a guide passage for guiding the belt.

The guide passage is generally downward and is arcuate along the right side of the indexing drum. A spring-loaded swivel pawl (39) is located at the end of the gate.
A fixed cutting blade (40) is also attached to one end of the gate.

When a new band is inserted, the leading clamping piece (10a) is pushed down and passes through the pawl (39), is placed between the swiveling pawl (39) and the blade (40), and the blade (40). Contacts the filaments (12a) (14a) of the leading fastening piece. At the position shown in FIG. 3, the claw (39) prevents the fastening piece (10a) from returning.

The gate then rotates in the direction of the drum and automatically stops.

By being fastened in this way, the first tightening piece (10
As shown in FIG. 3, a) engages with the recess at a position one step above the bottom of the drum, that is, at a position one step above the position where the hour hand indicates 6 o'clock.

When the gun is activated, the indexing drum rotates one step and carries the leading clamp to the bottom or 6 o'clock position. By this action, the leading clamp is moved past the fixed cutting blade (40) of the gate to separate the clamp from the band.

Strips (12) (14) are guided downwards out of the gate. For the belt, the tail of the fastening piece points toward the front of the gun,
The tail is engaged with the drum so that the serration side faces the drum shaft and the head projects from the drum shaft.

Therefore, once the leading fastening piece moves laterally to the bottom of the drum, that is, at the 6 o'clock position, the leading fastening piece is
It is arranged as shown in FIG. That is, the fastening piece (10a)
Has a tail facing forward of the gun, the serration side of the tail faces upward, and the head of the fastening piece projects downward.

This is the ready position of the clamp in the gun, with the tail at the front.

In this movement into the preparatory position, the tail of the fastening piece
Notched pinch wheel (42) and floating board (44)
Is inserted between and.

In front of the indexing drum there is a main pinch wheel (46) for driving the tail of the fastening piece from the front of the gun to the front. The purpose of the pinch wheel (42) is to apply initial power to the fastening piece to advance the tail of the fastening piece and engage the main pinch wheel (46).

The pinch wheel (42) acts on the upper side (serration side) of the tail, and the pressure plate (44) is a spring.
Deviated upwards, pushing the tail against the pinch wheel (46). The pressure plate (44) is pushed down by the head of the fastening piece while the fastening piece is being advanced by the main pinch wheel (46), and the fastening piece head can pass through the pressure plate (44). Like

The main pinch wheel (46) comprises teeth (47) whose profile is complementary to the lateral ratchet serration of the tail of the clamping piece. These teeth (47) mate with the serrations of the fastening piece to add a positive drive to the fastening piece in the form of a rack and pinion drive.

A cam wheel (48) is located below the main pinch wheel (46) and is normally stationary so that it provides a reaction surface for the main pinch wheel. The fastening piece is driven between the main pinch wheel and the cam wheel.

The cam wheel has a ring (49) having a cylindrical outer surface (50), a portion of the peripheral portion of which is removed.

The ring (49) is connected on one side to the disc (51), the disc (51) having a larger diameter than the ring (49) and corresponding to the removed part of the ring (49). Thus, the concave portion (52) is provided in the peripheral portion. The other side of the ring (49) is open, but at its periphery is a flange (5
3) is installed.

The flange (53) corresponds from the cylindrical outer surface (50) of the ring to the radially outer portion of the disc (51).
The radially outer part (51a) of the disc (51) and the corresponding flange (53) on one side of the ring form a groove that is slightly wider than the tail of the fastening piece and allows this tail to pass (See Figure 5A).

The cam wheel is shown in its normal fixed position in FIGS. 4-7 and the reaction surface for the main pinch wheel (46) is the outer surface of the ring (49) adjacent the recess (52) ( 50).

The clamping piece can be advanced by the pinch wheel (46) until its head (16) arrives. When the fastening piece reaches the position shown in FIG. 5, the head (16) engages with the recess (52), the stylus (120) detects the arrival of the head, and the power is transmitted to the cam wheel. Then, the cam wheel is rotated 360 ° counterclockwise as shown in FIGS.

By this rotation, the rear end (54) of the recess (52) supports and advances the outer end of the head of the fastening piece.

Then, as the rotation continues, a curved transition (55) (provided on both the outer part (51a) of the disc and the flange (53)) supports the outer end of the head of the fastening piece, and Push the fastening piece forward.

Finally, the outer rim of the disc and flange bears against the outer end of the head of the clamp to complete the advancement. After this, the fastening piece is driven and passes through the opening (56a) of the passage portion (56),
As shown in FIG. 6, in this opening, the tail passes through the head (16) to complete the fastening piece.

From the front of the gun, when driving the tail forward, the tail of the clamp is guided along the nose loop guide. The guide consists of a fixed lower guide (57) and an upper guide (58) which is pivotally mounted at (59) for closing around the bundle of cables to be wound.

The guides (57) (58) are formed with grooves (57a) (58a) for receiving the tails of the tightening pieces and suppressing lateral movement. First, the tail of the fastening piece is guided along the lower guide (57) and then along the upper guide (58) and finally at the front of the passage (56) in the downward groove (6).
You will be guided within 0).

At the end of the fastening piece drive step, the head is placed inside the threading device opening (56a), but the tip of the tail of the fastening piece (18) is slightly away from the head of the fastening piece, Aligned downward with respect to the opening (26) through the head of the fastening piece. The fastening piece at this stage is shown in FIG.

At this point in the operating cycle, power is transmitted to the threading device element, which is lifted to lift the head of the clamp. Since the free end of the tail is immovable, the lifting of the head of the fastening piece causes the tail to pass through the head opening (26) (where the tail engages),
It projects from the lower side of the head (see FIG. 7).

Next, the threading device (56) is lowered to return to the normal position. At this time, the head of the fastening piece and the end portion of its tail are carried (the tail of the fastening piece has the claw (28) in the head (16)).
Are in mesh with each other. ).

Therefore, the end of the tail protruding from the lower side of the head of the fastening piece is inserted into the nip between the pinch wheel (61) and the fixed reaction plate (62) as shown in FIG. Power is transmitted to the pinch wheel (61) and the tail is pulled downward through the head. Therefore, the fastening piece is pulled around the bundle of cables.

The pinch wheel (61) has teeth complementary to the serrations of the clamping pieces to provide a positive rack and pinion type drive. A device is installed to detect when the tensile stress in the tail reaches a predetermined magnitude and, in response, to transmit power to the actuator.

This actuator has a cutter blade (63) for the tail.
To cut the tail just below the head.

Motors (72) as the power source for all working parts of automatic guns
Is provided. By pressing the trigger (75)
The gun works. The upper guide (58) is rotated downward to close the lower guide (57) and the upper guide (58). The solenoid (85) is activated to stop the upper guide (58) in this position. Also, by operating the motor (72),
Allows indexing of the drum (30) and pinch wheel (42)
(46), the cam wheel (48), the passing portion (56), the pinch wheel (61), and the cutter blade (63) are driven. Pressing the trigger (75) activates the timing circuit. At the end of the timing circuit delay, the motor (72) is stopped, the solenoid (85) is deactivated and the nose loop guide is opened. The timing circuit delay is one gun cycle. That is, the drum (30) rotates to move the next tightening piece to the position shown in FIG. 4, advance the previous tightening piece to the position shown in FIG. 6, and set the threading device shown in FIG. 7 and FIG. It is during the reciprocation and pulling of the fastening piece to cut the free end of the fastening piece tail of FIG.

Structure of Automatic Gun for Tightening Piece FIGS. 9 to 12 show the gun with the casing removed.

The gun comprises a chassis having two parallel plates (70) (71) extending from the rear to the front. A motor (72) is mounted above the rear part of the chassis together with a drive shaft (73) oriented in the length direction of the gun.

A trigger (75) is attached to a handle (74) of a normal piston grip type. The trigger is to start the winding cycle when the gun is activated. Nose loop guides (57) (58) are attached to the front of the chassis. An indexing drum (30) is located in the opening of the plate (70), which is along the right side of the chassis when viewed from the front of the gun. The gate (34) is located on the right side of the gun.

Along the outside of the plate (71) (ie, along the left side of the chassis as seen from the front of the gun), in response to the depression of the trigger (75), the upper guide (58) is moved to the lower guide (57). A coupling mechanism (76) for closing up is arranged.

Between the two parallel plates (70) and (71) there are two different drive, threading, pulling and cutting elements, namely the initial pinch wheels (4
2) and its pressure plate (44), main pinch wheel (46) and cam ring (48), threading device (56), tension pinch wheel (61) and reaction plate (62), and tail cutter blade (63). It is arranged.

An actuator for moving the indexing drum, the drive pinch wheels (42) (46), the cam wheel (48), and the threading device (56) between the plates (70) and (71). When,
Tension wheel (61) and tail cutter blade (6
3) A mechanism for transmitting power to an actuator for moving the actuator is arranged.

Nose Loop Guide Closure In FIG. 9, pressing the trigger (75) causes the trigger to pivot about the center of rotation (77). Arm (7
8) is supported by trigger (75) and pin (79)
Displace the main link (80) through. Therefore,
The stanchion consisting of links (81) (82) is extended almost straight and closed by pivoting the upper guide (58) around the pivot point (59).

The links (81) (82) swivel with each other and the lower links
The plate (71) and the main link (at the midpoint) (8
Note that it is pivoted at 0). The upper link (82) is pivotally attached to the rearwardly extending motion arm (83) of the upper guide. Arm (78)
Press the micro switch (84) and solenoid (85)
Apply voltage to.

The solenoid armature (86) is connected to the main link (80) to further displace the link by a small amount. Therefore, the linearity of the links (81) (82) is perfected, and the guides are prevented from being opened by the external force applied to the upper guide (58).

Drive of indexing drum The drive shaft (73) passes through the gear case (88) and the shaft (87).
Drive (Fig. 10). The gear (89) on the shaft (87) drives the input of the clutch (90) and the output (91) of the clutch drives the gear (92) on the rear end of the indexing drum (30). (See also FIG. 4). This clutch is a spring wound type clutch.

That is, the clutch has a helical spring (93) surrounding a cylindrical stem on the input and output elements. One end of this spring is fixed to the output part, and the other end of the spring is
It is fixed to a control cylinder (94) which surrounds the spring.

When this control cylinder rotates, the spring contracts freely, contracting over the cylindrical stems of the input and output elements,
The output element is thus driven by the input element (ie the clutch is engaged). When the micro switch (84) closes (when the trigger (75) is pressed),
A voltage is applied to the motor (72) and is transmitted to the gear (92) of the indexing drum via the power shaft (87) and the clutch (90). However, when the input part of the clutch rotates 360 ° (the control cylinder (94) also rotates 360 °), the stop (94 a ) on the outer surface of the control cylinder (94) (Fig. 9).
Reaches the detent (95) of the blade (96).

The detent (95) contacts the stop (94 a ) to stop the control cylinder and disengage the clutch.

The helical spring can no longer freely contract up to the cylindrical system of the input and the output. The indexing drum rotates for one step (1/5 rotation) and then stops.

The blade (96) is connected to the solenoid armature and rotates about the point (97) when the solenoid is energized. Then, the detent is, until it comes into contact with the stop (94 a), slides over the surface of the clutch control cylinder. The detent also has the effect of displacing the blade (95) in the direction of rotation.

At the end of the operating cycle, when the solenoid is de-energized, the spring (96 a ) acting on the blade (96)
The blade is swung away from the clutch, but again
Lift the blade from the plane corresponding to the paper surface of the figure. Thus, when the solenoid is re-energized, the detent (15) contacts the clutch limiting cylinder behind the stop and the control cylinder is free to rotate.

The drive shaft (87) of the pinch wheel is connected to the shaft (100) via gears (101) (102). The shaft (100) has a crown gear (103)
Is attached to transmit power to the bevel gear (104). The bevel gear (104) has a gear (10
It is fixed together with 5) and transmits the power from the crown gear (103) to the gear (105). (Figures 10 and 11A).
The gear (105) transmits power to the input element (106) of the clutch (107), and the input element (106) transmits power to the input element (108) of the clutch (109).

The clutch (109) is an input element (11) of the clutch (112).
It has an output element (110) for transmitting power to 1). The input element (111) is connected to the gear (113), and the gear (113) is connected to the gear (114). Gear (11
4) is on the drive shaft of the pull pinch wheel (61). The main pinch wheel (46) is supported by a shaft that supports one gear. This gear meshes with the gear (113) at the top of the gear (113).

The pinch wheel (42) is driven by a gearbox that meshes an input element with a gear (110). Therefore, power is continuously transmitted to the pinch wheel (42) while the motor is energized. The power is also continuously transmitted to the main pinch wheel (46) and the tension pinch wheel (61) until the tensile stress of the fastening piece reaches a predetermined magnitude, as described below.

When actuated, the cam wheel drive clutch (112) transmits power to the cam wheel, causing it to rotate to the required 360 °. The clutch (112) is a spring wound clutch,
Output element (115) and input and output elements (111) (11
It has a helical spring (116) connected to 6) and a control cylinder (117).

Normally, the latch (124) (see below) is connected to the control cylinder (1
17) engaging both recesses with the output element (116),
These prevent them from rotating. Therefore, the clutch is normally disengaged.

When the head of the fastening piece reaches the cam wheel, the stylus (12
0) unlatches and when unlatched, the clutch (112) engages to transmit power to the gear (118) fixed to the cam wheel (48) by the output element (116). It becomes a state.

The stylus (120) is located within the cam wheel ring (49) and is mounted for independent rotation about the same axis. The stylus (120) has a radial surface (121),
This surface strikes the front end of the head (16) of the fastening piece (before the head contacts the cam wheel). Therefore, the stylus (120) momentarily rotates around its axis.

The stylus (120) has a radial slot (122) which is located on the pin (123) on the control arm of the latch (124).
Receive. Momentary rotation of the stylus (120) causes the latch to swing about the pivot axis (125) and detent (1
26) is released from the control cylinder (117) and the output element (116) of the clutch (112).

The stylus (120) is rotated by the head of the clamp when the cam wheel pushes the head forward. Therefore, the head can pass the stylus. Then the spring (1) mounted around the pivot (125) of the latch
27) biases the latch in the return direction and the pin (123) moves to return the stylus (120) to its normal position.

Driving of Passing Portion When the operation of the automatic gun is started, the clutch (107) moves so as to displace the passing portion (56). The clutch (107)
Spring-wound clutches, input and output elements (106)
It has a helical spring (128) arranged around the cylindrical stem of (129) and a control cylinder (130) around the spring (128).

Usually, the control cylinder (130) is moved by a latch lever (131) engaged in a recess of the control cylinder.
It is locked against rotation (and the clutch is not engaged).

When the output element (115) of the cam clutch (112) approaches the end of 360 degree rotation, the protrusion (132) on the output element (115)
Strikes the latch lever (131) and pivots the lever (1
Momentarily rotate around 33) and disengage the latch from the control cylinder (130) of the passing clutch (107).

Thus, the clutch is engaged and the output element (129) of the clutch is driven 360 ° before the latch (131) again engages the recess in the control cylinder (130).

The output element (129) has an eccentric wheel (134) engaging one end of a link (135), the upper end of which is connected to a lever (136), which lever (136) is The front end is connected to the passage portion (56). Therefore,
By rotating the eccentric wheel (134) 360 °, the lever (13
6) first swivels upwards around the pivot (137),
Then, because it pivots downwards, the passage is raised and then lowered, as described above.

In the drive clutch (109) of the tail cutter, the input and output elements (10
8) (110) are typically connected by three protrusions (eg 140) on the surface of the input element (108).

These protrusions engage respective recesses in the engagement surface of the output element (110). The protrusions and the corresponding recesses are arranged at unequal angles in the element. Therefore, these elements only engage one another when the input element (108) is in a predetermined rotational position with respect to the output element (110).

A rocker (142) is attached to a pivot (143) on the outer side of the plate (70) and a tension spring (144) acts between the rocker (142) and the plate (70).
The screw (145) allows adjustment of the rotational force applied to the rocker (142) by the tension spring (144). The rocker (142) is biased by a tension spring against the end of the shaft (146) to which the input element (108) is journal mounted.

When a predetermined tensile stress is generated in the tail of the tightening piece being pulled, the pull pinch wheel (61) feels a corresponding predetermined load.

This load is fed back to the output element (110) of the clutch (109) through the gears (113) and (111). Thus, if the load on the output element (110) is sufficiently different from the power applied by the input element (108),
The elements (108) and (110) are such that the projections (10) of the element (108) reach the complementary cam surface (147) on the engaging recess of the element (110).
The engagement is released by 4). Therefore, the input element (10
8) is displaced in the axial direction.

The value of the load produced by this process is determined by the axial direction which biases the elements (108) and (110) together, the force being determined by the tension spring (144).

In this way, when the elements (108) and (110) are disengaged, the output element (110) is no longer driven and thus
Main Pinch Wheel (46) and Tension Pinch Wheel (61)
The drive with and is interrupted. Further, the dock ring (150) (fixed to the element (108)) is moved to the dock ring (151) (the eccentric wheel (152)) by the axial displacement of the input element (108) (away from the output element (110)). Is fixed to)). Also, the input element (108) is the output element (1
Before recombining with 10), ie the projection (1) of the input element (108)
40) before recombining with the cam surface of the output element (110),
The input element (108) must rotate 360 degrees. During this 360 degree rotation of the input element (108), the detent (15
One end of 4) engages with the teeth of the output element (110) to prevent the output element (110) from rotating. So the input element (1
As 08) moves axially, the shaft (146) with the input element (108) attached moves upwards in FIG. The shaft (146) supports the rocker (142), and rotates the rocker (142) around the pivot (143) counterclockwise at a small angle. First
As shown in FIGS. 2A and 12B, the lever arm (153) engages the rocker (142) at one end and the detent (154) at the other end. As shown in FIGS. 11A and 12A, as the rocker (142) rotates clockwise, the lever wheel (153) causes a downward force on the detent (154) by a spring acting on the wheel. It can be rotated counterclockwise as shown in FIG. 12B. Thereby, the free end of the detent (154) engages the teeth of the output element (110).

By the end of this rotation, the tail of the clamp is cut as follows. The eccentric wheel (152) engages with the plate (155) supporting the cutter blade (63), and the rotation of the eccentric wheel (152) causes the plate (152) to reciprocate to move the blade forward and the tail. The plate is then returned to its normal spring-biased position.

Waste Discharge The cut portion of the tail of the clamp is sent by a wheel (160) to a lower waste bin (not shown). Power to the wheel (160) is supplied from the gear (111). The plate (161) acts as a reaction to this wheel (160) (see FIG. 10).

In FIG. 3, the gate is provided with an axis (170), and the axis (170)
Is a knurled roller (172) facing from front to back and near its ends aligned with strips of strips (12) (14)
have. In addition, the shaft (170) has a gear which is the gear of the indexing drum (92) when the gate is closed.
Mesh with.

The strips (12) (14) pass between a roller (172) and a reaction surface (174) formed on the gate.
This roller is a strip (1) from the gate after the last clamp on the strip is fed into the ready position at the bottom of the drum.
2) Move to send out the final part of (14).

The gate is opened by the user touching the release key with the finger of the hand without the gun, and the gate assumes the receiving position under spring excursion. After this, when the gate is pushed into the operating position, the gate is automatically latched.

[Brief description of drawings]

FIG. 1 is a plan view of a fastening strip according to the invention. FIG. 2 is a sectional view taken along line II-II in FIG. FIG. 3 is a schematic view of the gun gate and indexing drum device simplified to clearly show the operating principle. Figure 4 shows the gun indexing drum and the main tie drive elements,
It is the simplified schematic side view which shows the operation principle with a passage part. FIG. 5 is a view of the gun's cam wheel at the point of attempting to act on the head of the clamp in order to advance the clamp from the gun in the final part of its travel. FIG. 5A is a schematic sectional view taken along the line VA-VA in FIG. FIG. 6 is a schematic cross-sectional view of the nose loop guide of the gun, showing the clamp piece guided along this loop at the end point just about to be pushed out of the gun. FIG. 7 is a view similar to FIG. 6, showing a state in which the passing portion lifts the head of the fastening piece and passes the tail of the fastening piece through the head. FIG. 8 is a view similar to FIG. 6 when the passage portion is lowered again. FIG. 9 is a side view of the gun embodiment with the casing removed. FIG. 10 is a view of the gun seen from the same side as FIG. 9, and in order to show the working mechanism of the gun, the mechanism is simply and several It is shown without the parts. 11A and 11B are views from below and from the direction of arrow A in FIG. 10, respectively, showing various gear trains and transmissions in detail. 12A and 12B are views seen from below,
And FIG. 12A is a cross-sectional view taken along the line XIIB-XIIB of FIG. 12A, showing the actuating latch for tensioning and cutting the clamp. (1) Fastening strip, (10) Fastening strip (10a) Leading fastening strip, (12) Strip (12a) filament, (14) Strip (14a) filament, (16) Fastening strip head (18) Tail tip, (22) Ratchet serration (26) Opening, (28) Claw (30) Drum, (32) Recess (36) Shaft, (38) Slot (39) Swivel Claw, (40) Fixed cutting blade (42) Pinch wheel, (44) Pressure plate (46) Main pinch wheel, (47) Tooth (48) Cam wheel, (49) Ring (50) Outer surface, (51) Disc ( 51a) Radially outer portion of the disc, (52) recess (53) flange, (54) recess rear end (55) curved transition portion, (56) passage (56a) opening, (57) lower guide ( 57a) groove, (58) upper guide (58a) groove, (59) pivot point (61) pinch wheel, (62) reaction plate (63) cutter blade, 70) (71) plate (72) motor, (73) drive shaft (74) handle, (75) trigger (76) coupling mechanism, (77) center of rotation (78) arm, (79) pin (80) main link , (82) link (84) micro switch, (85) solenoid (86) armature, (87) shaft (88) gear case, (89) gear (90) clutch, (91) output (92) gear, (93) spiral spring (94) control cylinder, (94a) stop (95) detent, (96) blade (96a) spring, (100) shaft (101) (102) gear, (103) crown gear (104 ) Spur gear, (105) gear (106) input element, (107) clutch (108) input element, (109) clutch (110) output element, (111) input element (112) cam clutch, (113) (114) ) (115) (116)
Output Elements (117) Control Ring, (118) Gear (120) Stylus, (121) Radial Surface (122) Slot, (123) Pin (124) Latch, (125) Pivot Shaft (126) Detent, ( 127) spring (128) spiral spring, (129) input element (130) control cylinder, (131) latch lever (132) protrusion, (133) pivot (134) eccentric wheel, (135) link (136) lever, (137) Pivot (140) Protrusion, (142) Rocker (143) Pivot, (144) Extension Spring (146) Shaft, (147) Cam Surface (150) (151) Dog Ring, (152) Eccentric Wheel (153) Lever wheel, (155) plate (160) wheel, (170) shaft (172) roller, (174) reaction surface

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Paul Hans CB, England ３ ３ KYUV KENBRIGHT 32 Canterbury Street (56) References JP 55-29848 (JP, B2) JP 58-3232 (JP, B2) ) British Patent 2072614 (GB, A)

Claims (1)

[Claims] Claim: What is claimed is: 1. An automatic gun for winding a flexible, integral plastic clamping piece around a cable-like bundle, each clamping piece (10) having a flat tail. Has a tip at one end, a head (16) having an opening at the other end, and a plurality of serrations (22) on one side, and the automatic gun is such that the one end of the fastening piece is close to the front of the gun. Then, a means (30) for advancing each fastening piece at a predetermined position where the head (16) is separated from the front part of the gun, and the fastening piece at this predetermined position with the tail at the front of the front part of the gun Means for driving (42) (46) (48)
And guide the clamp tab around the bundle to be wound so that the clamp is driven from the gun and the tip of the tail passes through the head (16) and is linked therein. Therefore, the guide means (57) (58) provided at the front end of the gun is provided to drive the pinch wheel (46) and the pinch wheel (46) by means of driving the fastening piece tail from the gun. The drive means (111) (112) (113) for rotating and a cam wheel (48) which is normally stationary are provided, and the pinch wheel (46) and the cam wheel (48) are provided with the guide means (57). )
Located rearward of (58) and spaced so as to sandwich the flat tail of the clamp between them, said pinch wheel (46) engaging serrations on said one side of the tail and on the opposite side thereof. The outer surface of the cam wheel (48) (5
0), the fastening piece is driven forward by the rotation of the pinch wheel (46), and the cam wheel (48) is provided with a recess (52). The head (16) of the fastening piece is accommodated in the recess (52), and the head (16) of the recess (52) is further accommodated.
Of the driving means (111) (112) (11
3) is provided with means (120) for rotating the cam wheel (48) by 360 degrees, and when the cam wheel (48) rotates, the recess (52) supports the rear end of the head (16). 54) (55), an automatic gun for a fastening piece adapted to push the fastening piece to the final position of the forward movement.